Search

Your search keyword '"Aerospace engineering"' showing total 385,721 results
Start Over Descriptor "Aerospace engineering"

Refine your results

more »

more »

more »

more »

more »

more »

more »

more »
385,721 results on '"Aerospace engineering"'

1. A State-Space Method for Vibration of Double-Beam Systems with Variable Cross Sections

Author

Li, Yongxue, Guo, Hui, Xiong, Feng, Xie, Lingzhi, Gong, Jian, and Sun, Lizhi

Subjects
Engineering, Aerospace Engineering, Double-beam system, Variable cross section, Transverse vibration, State-space method, Civil Engineering, Mechanical Engineering, Civil engineering, Mechanical engineering
Abstract

In this paper, a state-space method for double-beam systems with variable cross sections is developed, making it possible to calculate the transverse vibration of the double-beams accurately and effectively. Due to the variability in the double-beam cross sections with the viscoelastic interlayer in between, the governing equations of vibration for the systems become highly coupled partial differential equations, making the problem difficult to solve. A basic double-beam system is introduced to modify the original governing equations to two inhomogeneous differential equations. Given the separation of variables, several mode-shape coefficients and a state variable are defined to construct the state-space equations. The coupling terms and variables are transferred into the constant coefficient matrix of the state-space equations, decoupling them. Numerical procedures are presented to solve the state-space equations to obtain homogenous and inhomogeneous solutions, including the natural frequencies and mode shapes in free vibration and the dynamic responses in forced vibration, respectively. The method has substantial advantages in decoupling high-order partial differential equations and can be further extended to solve complex structural systems. Numerical results also demonstrate that the method is accurate and efficient. Finally, an engineering application with a rail-bridge with a floating slab track is discussed in detail with the method.

Published
2024

2. Data-driven airfoil shape optimization framework for enhanced flutter performance

Author

Jung, Jiyoung and Gu, Grace X

Subjects
Engineering, Aerospace Engineering, Mathematical Sciences, Physical Sciences, Fluids & Plasmas, Mathematical sciences, Physical sciences
Abstract

This paper presents a machine learning-based airfoil shape optimization framework designed to increase flutter resistance and reduce drag. Using the National Advisory Committee for Aeronautics airfoil as the base design and a Hicks–Henne bump function, we employ multi-objective Bayesian optimization and harmonic balance-based flutter prediction. The optimization process yields a Pareto front revealing trade-off relationships between the flutter speed index and drag coefficient. The optimized airfoils, resembling those of evolved marine animals, outperform the base design in terms of flutter resistance and drag. These results demonstrate the framework's potential to enhance aircraft performance and safety by addressing aeroelastic factors.

Published
2024

4. A Numerical Simulation of PFPE Lubricant Kinetics in HAMR Air Bearing

Author

Tom, Roshan Mathew, Cheng, Qilong, and Bogy, David B

Subjects
Engineering, Aerospace Engineering, Heat-assisted magnetic recording, Air bearing, Lubricant, Smear, Materials Engineering, Mechanical Engineering, Mechanical Engineering & Transports, Materials engineering, Mechanical engineering
Abstract

Abstract: This report investigates the kinetics of lubricant molecules in the HAMR air bearing to understand the initiation and growth of PFPE contamination on the head surface. The collisions with the air bearing induce three forces—drag, thermophoresis, and lift. Of these, we find that lift forces are negligible. Then, a sensitivity analysis of the remaining two forces reveals the conditions where they dominate. Further, a hybrid simulation strategy is utilized to track their movements. The results show that the contaminations (smear) highly depend on the interplay between the thermophoresis and drag forces. We then explain the mechanism of the formation of the various observed patterns. Finally, we offer some recommendations to exploit the air bearing to contain smear on the head.

Published
2024

5. Methodology for Assessing Retrofitted Hydrogen Combustion and Fuel Cell Aircraft Environmental Impacts

Author

Alsamri, Khaled, De La Cruz, Jessica, Emmanouilidi, Melody, Huynh, Jacqueline, and Brouwer, Jack

Subjects
Aircraft, Fuel Cell, Hydrogen, Hydrogen Fuel cell, Engineering, Aerospace Engineering, Climate Action, Hydrogen Fuelled Aircraft, Proton Exchange Membrane Fuel Cells, Hydrogen Combustion, Cessna Citation, Cost Effectiveness, Liquid Hydrogen, Hydrogen Propulsion, Hydrogen Storage, Hydrogen-Powered Aircraft, Aircraft Propulsion, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Mechanical Engineering, Aerospace & Aeronautics, Aerospace engineering
Abstract

Hydrogen (H2) combustion and solid oxide fuel cells (SOFCs) can potentially reduce aviation-produced greenhouse gas emissions compared to kerosene propulsion. This paper outlines a methodology for evaluating performance and emission tradeoffs when retrofitting conventional kerosene-powered aircraft with lower-emissionH2 combustion and SOFC hybrid alternatives. The proposed framework presents a constant-range approach for designing liquid hydrogen fuel tanks, considering insulation, sizing, center of gravity, and power constraints. A lifecycle assessment evaluates greenhouse gas emissions and contrail formation effects for carbon footprint mitigation, while a cost analysis examines retrofit implementation consequences. A Cessna Citation 560XLS+ case study shows a 5% mass decrease for H2 combustion and a 0.4% mass decrease for the SOFC hybrid, at the tradeoff of removing three passengers. The lifecycle analysis of green hydrogen in aviation reveals a significant reduction in CO2 emissions for H2 combustion and SOFC systems, except for natural-gas-produced H2 combustion, when compared to Jet-A fuel. However, this environmental benefit is contrasted by an increase in fuel cost per passenger-km for green H2 combustion and a rise for natural-gas-produced H2 SOFC compared to kerosene. The results suggest that retrofitting aircraft with alternative fuels could lower carbon emissions, noting the economic and passenger capacity tradeoffs.

Published
2024

6. Effect of superhydrophobic surfaces on rod bundle flow dynamics

Author

Rodriguez, Angel F and Mäkiharju, Simo A

Subjects
Fluid Mechanics and Thermal Engineering, Engineering, Aerospace Engineering, Mechanical Engineering, Interdisciplinary Engineering, Fluids & Plasmas
Abstract

Pressurized water reactors are designed to operate in a single-phase flow. However, during a flow loss or other off-design conditions liquid temperature may exceed saturation temperature and, if a continuous film of gas forms, a boiling casualty may result. If superhydrophobic surfaces are introduced among the fuel cell assembly, vapor bubbles show an affinity to these surfaces and gas may coalesce to escape faster, resulting in a larger margin to reach critical heat flux. In the present study, we consider air and liquid water mixture examining the overall flow dynamics in a case with no bulk liquid flow, reminiscent of a case with coolant pump failure. The parameter ranges examined span Reynolds number based on gas superficial velocity up to 5300 and produced bubble with bond numbers from 1 to 270, and Weber numbers based on estimated terminal velocity from 0.6 to 150. The Morton number was fixed at 2.63×10-11. As the flow with high gas volume fraction becomes optically opaque and is sensitive to intrusive instrumentation, a custom-built photon-counting dual energy threshold X-ray computed tomography system is employed for measurement of the time average void fraction within the bundle non-intrusively. Two dual plane wire mesh sensors upstream and downstream of the rod bundle are employed to obtain comparison void fraction, velocity profiles and bubble size distributions. Additionally, traditional pressure-based gas holdup measurements are employed to calculate time- and volume-averaged void fraction. The data show that the presence of superhydrophobic surface being present in the rod bundle results in a significantly lower gas volume fraction and higher localized void fraction at the superhydrophobic coating, as compared to those in a similar rod bundle without superhydrophobic internals. Graphical abstract: (Figure presented.)

Published
2024

Catalog

Books, media, physical & digital resources
See catalog results